N-Alkyl-2-Quinolonopyrones Demonstrate Antimicrobial Activity against ESKAPE Pathogens Including Staphylococcus aureus

Antibiotic resistance has grown significantly in the last three decades, while research and development of new antibiotic classes has languished. Therefore, new chemical frameworks for the control of microbial behavior are urgently required. This study presents a novel suite of compounds, based on a tricyclic 4-hydroxy-2H-pyrano[3,2-c]quinoline-2,5(6H)-dione core, with significant antibiotic activity against the ESKAPE pathogens Staphylococcus aureus and Enterococcus faecalis and the “accidental pathogen” Staphylococcus epidermidis. A potent analogue with an N-heptyl-9-t-Bu substitution pattern emerged as a hit with MIC levels ≤2 μg/mL across four strains of MRSA. In addition, the same compound proved highly potent against Enterococcus spp. (0.25 μg/mL).

A ntimicrobial resistance (AMR) poses a significant challenge to society, one that if unmet, will result in significant mortality from infections that are currently manageable in the clinic. The "perfect storm" of increased resistance within populations of key opportunistic pathogens (such as the ESKAPE group: Enterococcus sp., Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumanii, Pseudomonas aeruginosa, and Enterobacter sp.) and a decline in the "discovery" of new antibiotic classes is of serious concern. 1 Apart from antibiotic stewardship, the key to addressing this challenge remains the development of new and effective antimicrobials, and yet, we are approaching three decades of what has been described as the discovery void. 2,3 New antibiotics brought to market over the last 30 years have typically been modifications of existing antibiotic classes, whereby mechanisms of resistance tend to be selected for within a very short period of time.
4-Quinolones are well-established as broad spectrum antibiotics. 4 In addition, 4-quinolones (in particular, 2-alkyl-4-(1H)-quinolones (AHQs)) have been identified as "signaling" molecules in a number of bacterial species. 5 Signaling enables microbes to communicate effectively at the population level, both within species (intraspecies) and across the species/ kingdom divide (interspecies/interkingdom). 6 The Pseudomonas quinolone signal (PQS) and its des-hydroxy precursor (HHQ) are particularly well-established as AHQ signals in Pseudomonas aeruginosa. 7 There is also some literature precedent that describes the antibacterial and antifungal activity of HHQ, PQS, and their synthetic analogues. 8,9 So, while SAR studies of the 2-alkyl-4-quinolones have been well-developed in numerous contexts, there are no reports on the corresponding N-alkyl-2-quinolones ( Figure 1). We initially sought to investigate the bioactivity of N-alkyl-2quinolones in a number of highly relevant bacterial species. We first prepared N-alkyl-2-quinolones based on a convenient method described by Lutz and co-workers. 10 Following alkylation of anthranilic acid, O-acetoxy quinolones could be formed by refluxing with acetic anhydride in acetic acid.
This method was not well-suited to the synthesis of analogues about the carbocyclic ring, as substituted anthranilic acid derivatives are not very readily accessible. 11 Instead, we proposed that substituted N-alkyl anilines would react with 1 equiv of diethyl malonate in a high boiling point solvent to give the same quinolone product. However, instead, we observed the formation of tricyclic 4-hydroxy-2H-pyrano[3,2-c]quinoline-2,5(6H)-dione derivatives. 12 Compounds of this type have been described before, although synthetic studies are limited. 13,14 Our efforts to prevent "overreaction" with dimalonate were not successful. However, we were presented with convenient access to two different groups of compounds possessing structural features relevant to or required for various bioactivities (see Supporting Information). Thus, compounds 1−13 were prepared via reaction of N-alkyl amine and diethyl malonate in refluxing diphenylether. Precipitation with hexane produced the desired 4-hydroxy-2H-pyrano[3,2-c]quinoline-2,5(6H)-dione derivatives (Scheme 1).
We first investigated inhibition of growth of a strain of methicillin-resistant S. aureus (MRSA) by N-alkyl-2-quinolones (10 in total) with different alkyl chain lengths (see Supporting Information). Unfortunately, none of the compounds displayed any antibacterial activity (data not shown).
We then tested pyranoquinolone 2 (Scheme 1) possessing an n-heptyl group, as this is a direct analogue of HHQ. Intriguingly, initial observations suggested excellent anti-MRSA activity, which warranted further investigation, both in expanding the types of structures tested and the bacterial strains they were tested against. Thus, we broadened our examination of the tricyclic N-alkyl-pyranoquinolone scaffold by alteration of the N-alkyl group, affording 1−5. Minimum inhibitory concentrations (MICs) were obtained for a number of S. aureus strains, including methicillin-sensitive (MSSA) and -resistant (MRSA) strains, a vancomycin intermediate (VISA) strain, and a clinical daptomycin-resistant isolate (DapRSA) ( Table 1). Of the N-alkyl-pyranoquinolones tested, the n-hexyl, n-heptyl, n-octyl, and n-nonyl analogues (1−4) all showed better activity than the n-decyl analogue (5), which was substantially less active against most strains. An n-nonyl chain appeared optimal, with compound 4 possessing an MIC of 1− 4 μg/mL against all S. aureus strains tested.
The n-heptyl tricyclic N-alkyl-pyranoquinolone framework was chosen to conduct additional SAR studies by substitution on the carbocyclic ring. In general, substitution at the 9position was targeted, as this was the most accessible site synthetically. For the new analogues, compound 7, followed by compound 6 (t-Bu and F groups, respectively, at the 9position) were the most consistently potent across the S. aureus strains tested. Both compound 12 (n-hexyl group at the 9-position) and compound 10 (8,10-dimethyl) were inactive against the three initial S. aureus strains tested.
Interestingly, while the chloro derivative 9 showed poor activity in the GP021 and GP035 strains, it was potent against the other three test strains. Compound 7 stands out as being of interest for further development against MRSA.
It was interesting to note that MRSA strain ATCC 43300 appeared to be generally more susceptible across all the lead molecules. The cydAB genes previously shown to underpin susceptibility in S. aureus and S. epidermidis to the AQ derivative HQNO 15 were comparable in all test strains, and no ATCC-43300-specific synonymous SNPs were identified in comparison with the test strains.
We then turned to proteomic analysis, which we hoped might provide some insight into the molecular mechanism through which these compounds elicit their growth inhibitory effects. While the majority of proteins found to be differentially encoded in ATCC 43300 when compared with the other test strains were mobile genetic elements (typically transposases), a loss of function mutation in the gene encoding the surfaceattached protein SasA was unique to ATCC 43300 ( Figure 2). Surface-attached proteins have previously been shown to play a significant role in the host−pathogen interaction and with respect to antimicrobial resistance in S. aureus. 16,17 This will form the basis of further investigations that seek to uncover the molecular mechanism underpinning the differential sensitivity to quinolone derivatives reported in this study. Similarly, previously identified hotspot mutations of the quinolone antibiotic targets GyrA, ParC and ParE were only identified in ATCC 700699 (see Supporting Information).
To determine if the scope of activity was specific for the S. aureus species, MIC testing was broadened to test other ESKAPE pathogens (Table 2). It was observed that several compounds exhibited activity against some Staphylococcus epidermidis and Enterococcus spp. strains. In particular, compound 7 showed excellent potency against the S. epidermidis GP_033 (VISE) strain. While MICs against Enterococcus sp. GP_024 (Type Strain) were quite poor, ndecyl analogue 5, which had not been noteworthy in other assays, was quite potent against the GP_026 (VRE) strain.

ACS Medicinal Chemistry Letters pubs.acs.org/acsmedchemlett Note
In conclusion, we demonstrated very good antibacterial activity across a range of bacteria including a number of MRSA strains. Activity is underpinned by a relatively underexplored tricyclic 4-hydroxy-2H-pyrano[3,2-c]quinoline-2,5(6H)-dione core. A potent analogue with an N-heptyl-9-t-Bu substitution pattern emerged as a hit with MIC levels ≤2 μg/mL across five strains of S. aureus, including resistant isolates. In addition, the same compound proved highly potent against Enterococcus spp. (0.25 μg/mL).
Activity was observed at the species and strain level, perhaps unsurprising given the extensive phenotypic and genotypic heterogeneity evolving within microbial populations.
Finally, while the activity is biocidal, it is nevertheless interesting that the framework with longer alkyl chains (akin to signaling compounds such as PQS (Figure 1)) gives the best biological activity. Further investigation of the mechanisms of action of the compounds described herein may offer some valuable insights, and a precise approach where opportunistic pathogens are disarmed, or specifically targeted at species or strain level, could improve the clinical management of infection in the future.
Chemical synthesis. Details of the chemical synthesis and characterization of compounds are provided in the supplementary data.
MIC screening. Details of strains, culture conditions, and MIC screening protocols are contained within the supplementary data.
Comparative genomic analysis. Genome sequences were accessed through the PATRIC informatics interface. 18 Outputs were exported to Excel and screened visually for unique genes. BLAST analysis through the PATRIC platform enabled identification of CydAB proteins in test genomes, and alignments were performed using Clustal Omega.